Air-conditioning system and apparatus



23, ,9 0- J. B. M'ONCRIEF 2,187,932

AIR-CONDITINING SYSTEM AND APPARATUS Filed ilay 12, 1958 5' Sheets-Sheet 1 I ATTORNEYS m 0 m N ws |N.E M m Jan. 23, 1940.

B. MONCRIEF AIR-CONDITIONING SYSTEM AND APPARATUS Filed llay 12, 1933 5 Sheets-Sheet --2 INVENTOR C/AMES B. Maven M ATTORNEYS 3m ,1940. J. B. MONCR|EF I 2,187,982

AIR-CONDITIONING SYSTEM AND APPARATUS Filed May 12, 1933 5 Sheets-Sheet ATTORNEYS Jan. 23, 1940. 4. B; MC DNCRIEE- AIR-CONDITIONING SYSTEM ANDAPPARATUS Filed May 12, 1958 5 She ts-Sheet 4 IINVENTOR (/AMES B. MONCRIEF BY.

ATTORNEYS Jan. 23, 1940. r J. 51 MONCRIEF 2,137,982

AIR-CONDITIONING SYSTEM AND APPARATUS Filed ma 12. 1938 5 Sheets-Shet s INVENTOR (JAMESBMO/VCR/EF BY z ATTORNEYS Fatented Jan. 23,1940 I 2,187,882 sm-oonnmonmo srs'rnm Ann AEPABATU James B. Moncrlef, Copperhill, Tenn.

. Application May 12, 1938, Serial No. 207389 18 Claims.

This invention relates to improvements in aireonditioning system and apparatus.

An object of the invention is to provide an improved system and apparatus of .the above nature applicable to automotive vehicles.

Another object is to provide apparatus of the above type adapted to both summer and winter operation.

A further object is to provide animproved system of the above type including an absorption refrigerating device utilizing the exhaust heat of the vehicles engine. a i

A still further object is to provide a system and apparatus of the above type utilizing heat absorbed from the atmosphere by reversed refrigeration eflect during winter operation. H

Another object is to provide a system of. the above type utilizing heat from the engine to actuate the generator and "employing the cooling means of the engine to extract heat from the heat rejecting section of the system.

Still another object is to provide improved means to control the circulation of air for summer and winter operation. Other objects and advantages of the invention will be apparent during the course of the following description in connection with the accompanying drawings, in which Figure 1 is a partly broken away side view of the forward part of an automobile including a preferred form of the invention;

Figure 2 is a similar plan view of the same;

Figure 3 is a rear view of the rear wall of the engine compartment showing the air discharge and inlet in the passage space;

-Figure 4 is a front view of the refrigerating apparatus with the casing cut away to show the interior parts;

Figure 5 is a detail right side view of the blower and evaporator structures with the casing cut away on the line 5-5, Figure 4;

Figure 6 is a vertical sectional view on the line 6-6, Figure 4; a

Figure 7 is a partial horizontal section viewed downward on the lines 1-1,. Figure-4;

Figure 8 is a partial horizontal upwardly directed sectional'view on the line 8-8, Figure 4;

Figure 9 is a detail top view of. the top louvres;

Figure 10 is a fragmental vertical sectional view of the top louvres and ducts; 1

Figure 11 is a fragmental sectional view showing the louvresin open position for summer operation;

Figure 12 is a similar view showing the louvres closed for winter operation;

iii

Figure 13 is a diagrammatic top view showing the paths of air movement through the device in summer operation;

Figure 14 is a similar view showing the air movement during winter operation;

Figure 15 is a diagrammatic front view corresponding to Figure 13;

Figure 16 is a similar view corresponding to I Figure 14;

Figure 1'7 is a longitudinal sectional view of m the rear portion of a motor car showing an alternative form and location of. the invention, showing the parts arranged for winter operation;

Figure 18 is a diagrammatic side view of the alternative form illustrating the air circulation 15 in summer operation;

Figure 19 is a top view of the alternative form;

Figure20 is a front view of the same with the rear of the driver's seat-and other parts cut away; a

Figure 21 is a vertical sectional view of the alternative form of casing for the unit shown in Figures 17, 18, i9 and 20, parts of the refrigerating unit itself being removed to clarify the showing of the-air circulation through the various compartments during summer use;

Figure 22 is a sectional detail view of the air intake and control valve in the alternative form;

Figure 23 is a view similar to Figure 21 but arranged for winter operation; and 80 Figure 24 is an exterior plan view of the alternative refrigerating unit casing showing the air duct arrangement for winter operation.

Referring to Figm'es 1 and 2, the numeral generally designates an automobile having an internal combustion engine 3! provided with an exhaust manifold 32. A bracket 33 supports a casing 34 arranged transversely in the rear of the engine compartment above the engine 3|.

Referring to the front sectional view, Figure 4, it will be seen that the casing 34 comprises five interior compartments 35, 36, ill, 38 and 39.

The compartment contains a generator 40 forming Part of an absorption refrigeration systern and having an interior heating pipe 4|. A conduit 42,'preferably of the flexible metallic tim connects the exhaust manifold 32 with the heating pipe 4|, while a similar conduit 43 leads from the heating pipe I to the main exhaust pipe 44 of the automobile.

The compartment 31 contains the absorber 4B and condenser 48 of the refrigerating system, while the evaporator 41 is disposed in the compartment. The absorption refrigeration system illustrated is of the partial pressure type utllizing hydrogen in the evaporator and absorber and comprising the usual auxiliary parts such as the analyzer 48 .and heat exchangers 49 and 58.

It will be understood that the exact nature of the heat insulating material 5| at the bottom and extending up its side walls, the generator 48 being embedded approximately to its middle in the bottom insulation. A gas-tight partition 52, of. heat conducting material such as metal, separates the generator compartment from the overlying compartment 36, and fins 53 are provided on both sides of partition 52 to transfer heat from the compartment 35 to the compartment 36, as

hereinafter set forth.

The compartment 36 is insulated by means of material 5| on the interior of its sides and top except for an opening 54 in the upper corner leading into the absorber and condenser compartment 31. A shutter 55, shown in detail in Figures 9 to 12, is slidably secured inside the top 56 of the casing 34 so as to overlie the compartment 31, and has a downwardly extending angle 62, Figures 4 and 10. Diagonal push rods 58 and 59, Figure 9, extending outwardly through the casing 34 and guided therein, are secured to the shutter 55 and provide exterior means for sliding the shutter diagonally from left to right or vice versa.

The shutter 55 is provided with slots 68, Figures 9, 11 and 12, adapted to register with louvres 6| in the top 56, as shown in Figure 11, but held out of registry therewith as shown in Figures 9 and 12 when the device is adjusted for winter operation.

A downwardly depending angle 62 on the left end of shutter 55, Figure 4, closes the opening 54 when the device is. in summer operating posie tion, but clears the opening 54.when slid to the left, Figure 10, for winter operation. Set screws 63, Figure 9, are provided to hold the rods 58 and 59 and shutter 55 in either extreme position.

The compartment 38, housing the evaporator 41, is insulated by means of material 64. A blower 65, Figures 4 and 5, disposed in the compartment 39 and provided with an electric motor 66, has a discharge duct 61 connected for summer operation through an elbow 68, short pipe 69 and inlet collar 16 with the evaporator compartment 38. -A second collar 1|, leading into the condenser andabsorber compartment 31, is provided in line with the elbow 68 and is closed with a removable cap or plug 12 for summer operation. The elbow 68 is of the reversible type and for winter operation may be shifted to connect the pipe 69 to the second collar 1|, the first collar 10 being left open. Thus, it will be seen that the blower 65 discharges into the evaporator compartment 38 for summer operation and into the condenser-absorber compartment 31 in winter. The motor 66 is adapted to be energized by the car battery, and is controlled by a suitable switch (not shown) on the dash-board or instrument panel.

The compartment 9 may be open'to the atmosphere at the front, back or both, providing ventilation for the motor 66 and allowing outside air to enter the evaporator compartment 38 through the collar 18 during winter operation.

The blower 65 has an inlet duct 13 leading through the rear wall 14 01 but: engine compartment from the passenger compartment 15 of the car as shown in Figures 1 and 3. This inlet duct is provided with an air filter 16. A second duct 11 leads from the evaporator compartment 38 to the passenger space 15, and is equipped with directional fins 18 of a well-known type at its point of discharge under the dash board, Figure 3. A third. duct 19, which may also be equipped with directional fins (not shown) connects the compartment 36, Figure 4, with the passenger space. This duct 19 is closed by a cap or plug 80. for summer service. In winter service the cap is removed from duct 19 and used to close duct 11 as hereinafter set forth.

An air opening or collar 8|, Figures 7, 13 and 15, has connected thereto a pipe 82 extending forward over the engine 3| and terminating in inlet funnels 83 behind the radiator fan 84 of the engine so as to receive the blast of fan 84. For winter service, the pipe 82 may be removed from collar 8| and replaced by a closure cap 85 as shown in Figures 14 and 16. Obviously, if desired, the pipe 82 may be provided with a butterfly valve v 86 of the usual damper type operable by a handle 81, Figure 2, in which case this pipe may be left in place and closed off by means of the above valve for winter operation. Also, it is obvious that the directional shutters of the circulating ducts 11 and 19, Figures l and 3, can be made of thewell-known adjustable type adapted to be closed off entirely, in which case the cap 80 may be dispensed with. The pipe 82 normally is insulated to prevent it from picking up heat from the engine. In winter service the pipe 11 may also be removed, leaving the shutter 18 in place but open- 4 and 11, the louvres 6| being open and the opening 54, Figure 4, closed by the angle 62. I At the same time the blower 65 is connected as shown in Figures 4 and 5, with the air ducts 13 and 11 open to the passenger space 15. As the car is operated, the blast of air from the fan 84 and from the cars motion enters through the pipe 82 and collar 8| to the compartment 31, passes upward therethrough around the absorber 45 and condenser 46 and out the top louvres 6|, thereby cooling the condenser and absorber and discharging their heat to the air of the engine compartment.

The blower 65 being in operation and the ducts 13 and 11 open as shown in Figure 3, air from the passenger compartment 15 is drawn through the filter 16 to the blower 65 and forced through the evaporator compartment 38 and back into the space 15 through the directional vanes 18 of "the duct 11. In its passage over theevaporator 41 the air is cooled and partially dehydrated. It enters the passenger compartment at a lowered temperature and humidity to provide a comfortable atmosphere therein.

the shutter 55 is in the position shown in Figures A trap as, Figure 5, is provided to eliminatecondensate from the evaporator compartment 38.

From the foregoing it will be noted that in summer operation there are two separate air currents passing through the casing 34; the heat removal to the outside being furnished by a blast of air due to the engine fan and motion of the car, while the current of recirculating conditioned air is provided by the blower 65. The relative paths of the two air currents as described may readily be followed by reference to diagrammatic Figures 13 and 15.

For winter operation the shutter 55 in the top 56 of the casing 34 is shifted by means of the push-rod 59 to the position shown in Figures 9, 10 and 12, thereby closing the louvres 6| and freeing the opening 54 between the condenser-absorber compartment 31 and the compartment 36. The

. blower elbow is shifted as previously described and as shown diagrammatically in Figures 14 and 16, to discharge into the condenser-absorber compartment 31. The opening of duct 11 to the pas-' senger compartment, Figure 3, is closed and the duct 19 thereto is opened. The front air inlet collar 8i of the condenser-absorber compartment is closed, either by means of the butterfly valve 86 in the pipe 82 or by removal of the latter and substitution of the cap 85, Figures 14 and 16, as previously described.

The collar 10, Figure 4, is allowed to remain open to the atmosphere (the blower pipe 69 having been removed therefrom), and a second atmospheric opening to the compartment 38 may be provided if desired by removing the duct 11 while leaving its terminal closure 18 intact in the partition I8. By the above means it will be seen that a natural circulation of outside air can take place through the evaporator compartment 38,-

since the blower compartment 39 is open to the atmosphere as previously set forth.

In winter operation, with the above described arrangement, the blower 65 draws air from the passenger compartment through the inlet duct I3 and filter I6 and forces it into the condenserabsorber compartment 31, thence through the opening 56, down through the compartment 36 and back to the passenger compartment through theduct 19. In its passage through the compartment 31, the circulating air removes heat from the absorber 45 and condenser 46, while in its passage through the compartment 36 it receives additional heat given up by the generator 40 to the fins 53 and partition 52 and conducted thereby into the path of the air-stream in compartment 36.

The refrigerating system being in operation, the evaporator 41 is maintained at lower temperature than the outside air having access to it, and thus absorbs outside heat therefrom, this heat passing into the system to be given up to thecirculating air stream described. This additional heat absorbed from the outer air is thus made available Y through the passenger compartment is warmed both by heat taken up from the absorber 45, condenser 46 and related parts, this heat including the heat absorbed from the atmosphere by the evaporator 61, andby heat given up by the generator 40 and such portion of the heating exhaust pipe 41 as is exposed within the chamber 36. The heat from the generator and pipe 45 is given indirectly to the air-stream through the conducting fins 53 and gas-tight-partition 52, the latter making it impossible for any fumes which might be present in case of exhaust or other leakage in compartment 35 to be entrained in the air-stream and be carried into the passenger compartment.

Since in both summer and winter operation the circulation through the passenger space 35 is furnished by means of the blower 65, it is obvious that the speed of circulation may be adjusted at will in a well-known manner by means of the adjustable shutter on the discharge openings as previously noted.

In the alternative form of the deviceshown in Figures 17 to 24, the refrigerating .unit casing 69 is arranged in the rear or luggage compartment 90 in the car. The heater pipe Ma of the generator 60a is connected in the exhaust line between the main exhaust pipe 42 and. the mufiler 9 I.

Viewing the casing 89 from the rear in the sectional detail views 2I and 23, the numeral 35a denotes the generator compartment, 36a the compartment immediately above the latter and separated therefrom by the finned conducting partltion or sealing wall 52a, 37a the condenser-absorber compartment, and 3811 the evaporator compartment.

A ductv 92, Figures 21 and 23, leads along the top and down the side of the casing 89 outside the insulated evaporator compartment 36a and terminates in a rearwardly directed discharge scoop 53 open to the outside air below the car floor 95. A forwardly-directed inlet scoop 95, also depending below the floor 2a, is connected into the bottom of the absorber-condenser compartment 31a.

The compartments 36a and 38a have openings 96 and 91 respectively in their upper inward corners, Figures 21 and 23. A removable cover 90 has a fiat cross member 97a and a curved partition I00 adapted to close ofl'the openings 96 and 91 for summer operation as shown in Figure 21, the compartment 31a being in communication with the duct 92. The cover 98 is reversible to the position shown in Figure 23 for winter operation.

.In this position the evaporator compartment 38a III! which is directly connected to two blowers I02 and I03. The blower I 02 is permanently connected at its discharge side to the evaporator compartment 88a through a duct I04,while a similar duct I05 permanently connects the discharge of blower I03 with the lower part of the condenser-absorber compartment 31a. A pipe opening or collar I06 in the front wall of the compartment 36a is adapted to receive a warm air discharge pipe I01 leading into the passenger compartment 15 as shown in Figures 17 and 24 for winter operation, or to be capped as shown in Figures 18, 19 and 20 for summer operation.

A similar collar I08 in the forward wall of the evaporator compartment 36a connects the latter through a discharge pipe I09 with the passenger space 15 in summer, Figures 18, 19 and 20, and

may be capped in winter as shown in Figures 17 and connected to a screened inlet pipe Ill lead- 3 ing from the passenger space I5 and a cap H2 is used to close the opening into the hollow member 99. Similarly, the inlet elbow H3 of the blower I02 for summer operation is connected to an upwardly directed inlet pipe H4, but in winter is turned downward as shown in Figure 24 to connect into the cross duct Hill in the member 99. A cap H3a, Figure 20, may be used .to close the opening to the duct I vacated bythe elbow I I3 in summer use.

While to simplify theillustration and explanation, changes between winter and summer arrangements have been shown as made by shifting pipes and capped openings, it will be obvious to those skilled'in the art that the same result may be attained by permanent cross piping equipped with suitable dampers or valves such as 86, Figure 2.

A flapper check valve H, Figure 22, is provided in the inlet scoop 94 beyond the opening of the cross duct I00. A pair of small stops I I5 and H1 are arranged in the bottom of the scoop 94. In summer operation, when the car is in forward motion, the rush of air inward holds the valve open as shown in Figure 22. When the car stops the valve settles against the upper stop 1 I6, thus preventing back-draft down the scoop from the chamber 31a. The flapper is loosely hinged, and for winter operation may be raised and dropped between the stops H6 and H1, preventing entry of outside air to the chamber 31a.

The operation of the device, in its alternative form, is substantially the same as that described for the preferred form previously described, except for the use of the two blowers, one replacing the engine fan which of course is not available in that location. In summer operation, Figures 18, 19, 20, 21 and 22, the blower I03 draws air through the cross-duct I00 and inlet scoop 94 and forces it into the absorber-condenser compartment 31a through the opening I05. Additional outside air also rushes up the scoop 94 and past the valve H5 into compartment 31a. when the car-is in motion, as described above. These combined air streams move upward through compartment 31a as shown in Figure 21, removing the heat from the absorber and condenser (omitted from Figure 21 for clarity), and discharge to the outside through duct 92 and discharge scoop 93. Meanwhile, the blower I02 draws air from the passenger space 15 through inlet pipe H4, circulates it through the evaporator compartment 38a. where it is cooled and dehumidifled, and returns it to space 15 through the pipe I09.

During winter operation the blower 102 draws outside air through the scoop 94 and cross duct I00 and discharges it through opening 91, duct 92 and scoop 93 to the outside as shown in Figure 23. A draft of outside air is thus maintained over the evaporator during winter use, allowing the evaporator to absorb outside heat into the system for the reversed refrigerating efiect previously set forth. At the same time, the blower I03 draws air fromthe passenger space 15 through the screened inlet pipe Ill, Figures 17 and 24, forces it through the condenser-absorber compartment 31a as shown in Figure 23, thence through opening 96, compartment 36a, collar I06 and pipe I01 into the space 15. The air in passing through the circuit described receives heat from the absorber, condenser (omitted in Figure 23 as noted) and finned partition 52a to maintain a continuously heated re-circulation of air through the passenger space.

-It is obvious that the air inlets and outlets in thepassenger space may be arranged at any desired location, but those shown, namely high for summer operation and low for winter, are preferred as giving the most desirable distribution of cooled or warmed air respectively. 'Where the pipes project upward through a luggage shelf H8, as in Figures 18, 19 and 20, the screened head H9 on the inlet pipe I l 4 prevents objects from falling thereinand prevents blocking of the opening.

It has been noted that in the form and arrangement of the invention shown in Figure 1 the refrigerating means is actuated by heat applied thereto from the engine itself and that in summer operation heat is removed from the heatrejecting section of the system by means of the engines cooling means; namely, the fan 84 which provides the final heat removal from the radiator. When the device is in winter operation and the air pipe 82 is left in position as previously noted, the damper valve 86 instead of being completely closed may be cracked open slightly. This allows the blast, from the fan 84 to drive a small amount of fresh air into the circulating air stream in the condenser-absorber compartment, thus furnishing make-up air to replace leakage and provide additional oxygen in the passenger space. This make-up air having been drawn directly through the radiator, is partially preheated and thus requires little additional heat after mixing with the circulating air.

The invention has been described principally as applied to an automobile, but it is obvious that it may also be used advantageously in connection with internal combustion engines in many stationary installations, for example in the case of a stationary engine having an adjacent cab or room for the operator. It will also be understood that although the typical absorption refrigerating plant is shown as employing the hydrogen cycle, as previously noted, this need not be the case, since any suitable type of absorption plant may be used to provide the three elements including a heat application section, a heat rejecting section and a heat absorbing section.

While the invention'has been set forth in preferred form, it is not limited to the precise structures illustrated, as various changes and modifications may be made without departing from the scope of the appended claims.

What is claimed is:

1. In an automotive vehicle having a passenger space and a power plant including a fan, in combination, an absorption refrigerating device adjacent said power plant behind said fan and including a generator, a condenser, an evaporator and an absorber, means to conduct exhaust gases from said power plant in heat exchange relationship with said generator to operate said device, means operable by said fan to conduct a current of air over said condenser and said absorber, means independent of said fan to circulate a volume of air from said passenger space about said evaporator and back into said'space, means between said fan and said condenser and absorber to disable said conducting means, and means to divert said volume of air from said evaporator to said condenser and absorber.

2. In an air-conditioning system for an auto motive vehicle, said vehicle having a passenger space and a power plant including a fan, in combination, a casing behind said fan, a generator in said casing and operable by exhaust from said power plant, a condenser, an evaporator, an absorber cooperative with said generator, means to continuously circulate a current of air from said space through said casing and back'to said space, means in said casing to direct said current about said evaporator whereby said circulating air may be cooled and dehumidified, and means operable by said fan and by the motion of said vehicle to direct a second current of air through said casing about said absorber and condenser.

3. An air-conditioning system as claimed in claim 2, including means to disable said second,

directing means, a gas-tight partition of heat conducting material within said casing adjacent said generator, and means to divert said first current of air from said evaporator and over said absorber, condenser and gas-tight partition whereby said first current of air maybe heated, said evaporator being exposed to exterior air to absorb heat therefrom.

4. In an air-conditioning system for an automotive vehicle havinga passenger space and an internal combustion engine, in combination, an absorption refrigerating plant operable by exhaust heat from said engine, said plant including a generator, a condenser, an evaporator and an absorber, means to transfer heat from the air of said space to said evaporator to cool said space in warm weather, and means to transfer heat individually from said condenser, absorber and generator to said air to warm said space in cool weather, part of said last named heat being extracted by said evaporator from the outer atmos-' phere and part being derived from said exhaust through said generator.

5. In an automotive vehicle having an internal combustion engine and a passenger space, in combination, an absorption refrigerating system including a generator operable by exhaust heat of said engine and an evaporator adapted to extract additional heat from the outer atmosphere, and means totransfer said exhaust heat and said atmospheric heatfrom said system to said passenger space, part of said transferred heat being derived by radiation from said generator.

6. In an automotive vehicle including a passenger space and an engine having an exhaust system, in combination, a casing, an absorption refrigerating plant in said casing including a generator operable by heat of said exhaust system, said casing having a compartment adjacent said generator, a gas-tight partition of heat conducting material between said generator and said compartment, said partition having fins adapted to receive heat from said generator and to conduct said heat to said compartment, an

absorber and a condenser in said casing and cooperative with said generator, and means'to circulate a current of air about said absorber, about said condenser, through said compartment, and through said passenger space whereby said space may be heated.

-'7. The combination claimed in claim 6 including a second compartment housing said absorber and condenser and normally communicating with said first compartment, 8. third compartment,

an evaporator in said third compartment, means to close ofi communications from said first compartment to said second compartment and to said space, means to divert said circulating air current from said second compartment andto direct the same through said evaporator compartment whereby said space may be cooled, and

means to force a second current of air through said second compartment to the exterior 01 said vehicle.

8. In an automotive vehicle, in combination, an engine, a radiator fan operable by said engine, an absorption refrigeration system including a generator and a-condenser and an absorber, means to supply exhaust heat from said engine to said generator to operate the same, means to conduct air from said fan directly over said absorber and condenser to cool the same, and means to disable said directing means.

9. The combination claimed in claim 8 wherein said vehicle comprises a passenger space and including an evaporator cooperative with said said fan and adapted to circulate air through said closure and said space, and means to divert said circulated air fromsaid enclosure and directly over said condenser and absorber and in heat transfer relation with said generator.

10. In an automotive vehicle having a passenger space, in combination, an engine having a cooling radiator and a fan cooperative there with, a refrigerating system including a con densing section behind said radiator and fan and an evaporator section, means to direct the blast of air from said fan over said condensing section to cool the same, means between said fan and said condensing section to regulate said directed blast, and mechanical means independent of said fan to circulate air through said evaporator section and said passenger space.

11. In an automotive vehicle having a space to be air-conditioned and an engine compartment, in combination, an engine in said compartment, a radiator fan operable by said engine, a wall between said space and said compartment, a casing arranged in said engine compartment adjacent said wall, an air inlet duct leading from said space through said wall and to the interior of said casing, an air discharge duct leading from the interior of said casing through said wall to said space, an absorption refrigerating plant in said casing including a generator, a condenser, an evaporator and an absorber, means to transfer heat from the exhaust gases ofsaid engine to said generator to actuate said plant, a blower having its inlet connected to said inlet duct. means to direct the air current from said blower about said evaporator and through said discharge duct to' said space, said casing having air louvres, an air pipe connected into said casing and extending toward said fan, a funnel on said pipe adjacent said fan to receive the air blast thereof and direct the same into said casing, and means in said casing to direct said blast about said absorber ing to said space, said casing comprising a compartment containing said condenser and absorber, a shutter adapted to close said louvres and to open communication between said condenser-absorber compartment and, said second discharge duct, outlet means on said blower adjustable to expose said evaporator to the outer atmosphere and to direct the air current from said blower into said condenser absorber compartment and thence through said open communication and said second discharge duct to said space, means to close said first discharge-duct, and means to close said air pipe.

14. The combination claimed in claim 11 including a closure within said casing adjacent said generator, 9. gas-tight partition between said generator and said closure and adapted to conduct heat from said generator into said closure, a second discharge duct from said closure to said space, said casing comprising a compartment containing said condenser and absorber, a shutter adapted to close said louvres and to open communication between said condenser-absorber compartment and said closure, outlet means on said blower adjustable to expose said evaporator to the outer atmosphere and to direct the air current from said blower into said condenserabsorber compartment and thence through said closure and said second discharge duct to said space, means to-close said first discharge duct,

and adjustable means to close said air pipe.

15.'In an automotive vehicle, in combination, an internal combustion engine, means to cool said engine, a refrigerating system including a generator and a heat-rejecting section, means to apply heat from said engine to said generator, means operable by said engin cooling means to remove heat from said heat-rejecting section, means to disable said last named means, and means to transfer heat from said heat rejecting section and from said generator to the interior of said vehicle.

16. The combination claimed in claim 15 wherein said refrigerating system includes an evaporator section, and including means to transfer heat from said interior to said evaporator section.

17. In an air-conditioning system for a structure including a space to be air-conditioned and an internal combustion engine, in combination, an'absorption refrigerating plant comprising a section for heat application, a heat rejecting section and a heat-absorbing section; means to apply exhaust heat from said engine to said first section to actuate said plant, means to transfer heat from the air of-said space to said heat absorbing section to cool said space in warm weather, and means to transfer heat from said heat rejecting section and individually from said heat application section to said air to warm said space in cool weather. 1

18. In an air-conditioning system for a structure having a space to be air-conditioned and an internal combustion engine having cooling means, in combination, an absorption refrigerating plant operable by exhaust heat from said engine, means to transfer heat from the air of said. space to said refrigerating plant to cool said space in warm weather,means to transfer heat from said refrigerating plant to said air to warm said space in cool weather, part of said last namedheat being extracted by said plant from the outer atmosphere and part being derived from said exhaust through said plant, and means to introduce additional air into said space in cool weather, said additional air being pie-heated by said engine cooling means.

JAMES B. MONCRIEF. 

